A III-V semiconductor die for die crack detection is provided. The III-V semiconductor die includes a device area. The III-V semiconductor die further includes a doped semiconductor ring region. The doped semiconductor ring region surrounds the device area. At least one active device or at least one passive device is formed in the device area of the III-V semiconductor die.

A method for fabricating high electron mobility transistor (HEMT) includes the steps of forming a buffer layer on a substrate, forming a barrier layer on the buffer layer, forming a p-type semiconductor layer on the barrier layer, forming a titanium nitride (TiN) layer on the p-type semiconductor layer as a nitrogen to titanium (N/Ti) ratio of the TiN layer is greater than 1, forming a passivation layer on the TiN layer and the barrier layer, removing the passivation layer to form an opening, forming a gate electrode in the opening, and then forming a source electrode and a drain electrode adjacent to two sides of the gate electrode on the barrier layer.

A lateral III-N device has a vertical gate module with III-N material orientated in an N-polar or a group-III polar orientation. A III-N material structure has a III-N buffer layer, a III-N barrier layer, and a III-N channel layer. A compositional difference between the III-N barrier layer and the III-N channel layer causes a 2DEG channel to be induced in the III-N channel layer. A p-type III-N body layer is disposed over the III-N channel layer in a source side access region but not over a drain side access region. A n-type III-N capping layer over the p-type III-N body layer. A source electrode that contacts the n-type III-N capping layer is electrically connected to the p-type III-N body layer and is electrically isolated from the 2DEG channel when the gate electrode is biased relative to the source electrode at a voltage that is below a threshold voltage.

A semiconductor device includes a first and a second switching element, a first and a second conductive member, and a capacitor. The first switching element has a first element obverse surface and a first element reverse surface facing away from each other in a first direction. The second switching element has a second element obverse surface and a second element reverse surface facing away from each other in the first direction. The first and second conductive members are spaced apart in a second direction orthogonal to the first direction. The capacitor has a first and a second connection terminal. The first and second switching elements are connected in series, forming a bridge. The first and second connection terminals are electrically connected to opposite ends of the bridge. The capacitor and the first switching element are on the first conductive member, the second switching element on the second conductive member.

A p-GaN gate tunnel junction HEMT includes a nucleation layer, buffer layer, nitride-based channel layer, nitride-based barrier layer, p-type GaN layer, gate electrode, source electrode, drain electrode, and surface passivation layer. The nucleation and buffer layers are disposed on a substrate, with the nitride-based channel layer above. The nitride-based barrier layer is positioned on the nitride-based channel layer, creating a 2DEG channel between the channel and barrier layers. The p-type GaN layer is positioned on the nitride-based barrier layer. The gate electrode is positioned on the p-type GaN layer. The source electrode forms a tunnel junction with the 2DEG channel, and the drain electrode is placed on the nitride-based barrier layer. The passivation layer covers the nitride-based barrier layer with portions between the gate-source and gate-drain regions.

Various embodiments of the present disclosure are directed towards an integrated chip a first undoped layer overlies a substrate. A first barrier layer overlies the first undoped layer and has a first thickness. A first doped layer overlies the first barrier layer and is disposed laterally within an n-channel device region of the substrate. A second barrier layer overlies the first barrier layer and is disposed within a p-channel device region that is laterally adjacent to the n-channel device region. The second barrier layer has a second thickness that is greater than the first thickness. A second undoped layer overlies the second barrier layer. A second doped layer overlies the second undoped layer. The second undoped layer and the second doped layer are disposed within the p-channel device region.

A semiconductor device is provided. The semiconductor device includes a substrate, a semiconductor layer, a device layer, and heat dissipating structures. The semiconductor layer is over the substrate and the device layer is over the semiconductor layer. The device layer includes a first ohmic contact and a second ohmic contact. The heat dissipating structures are at least through the substrate and the semiconductor layer, and between the first ohmic contact and the second ohmic contact.

An apparatus for reducing lag includes a substrate; a group III-Nitride barrier layer; a source electrically coupled to the group III-Nitride barrier layer; a gate on the group III-Nitride barrier layer; a drain electrically coupled to the group III-Nitride barrier layer; a p-region being arranged at or below the group III-Nitride barrier layer; and a gate control circuit configured to control a gate voltage of the gate. Additionally, at least a portion of the p-region is arranged vertically below at least one of the following: the source, the gate, and an area between the gate and the drain.

One or more systems, devices and/or methods of fabrication provided herein relate to forming a strained ohmic contact on a high electron mobility transistor (HEMT) semiconductor device. According to one embodiment, a plurality of semiconductor layers that comprises a barrier layer on top of a quantum well layer is formed and, a T-gate is placed above a plurality of semiconductor layers and between a first doped contact layer and a second doped contact layer. According to another embodiment, a tensile strained (TS) contact layer is deposited on the first and the second doped contact layer, wherein the TS contact layer is a stiff metal deposited with tensile internal stress, and wherein a linear expansion coefficient as a function of temperature of the stiff metal is larger than the linear expansion coefficient of the plurality of semiconductor layers, to induce a reduction of tunneling resistance through the barrier layer.

Semiconductor heterostructures having an engineered polarization. Semiconductor materials having specified crystallographic directions and specified polarizations are directly bonded to one another by means of atomic layer bonding without the use of any interfacial bonding materials, where spontaneous polarization of the two layers produced by joining the two materials by direct wafer bonding produces a strong 2DEG or 2DHG at the interface. Embodiments include GaN/AlN and AlN/GaN heterostructures having an N- or Ga-polar GaN layer directly bonded to an N- or Al-polar Al layer. Other embodiments can incorporate an InN epitaxial layer or an alloy incorporating an N-polar, Al-polar, or Ga-polar material having In, Al, or Ga in the crystal lattice, e.g., (In.sub.xAl.sub.1-xN), In.sub.xGa.sub.1-xN, Al.sub.xGa.sub.1-xN, In.sub.xAl.sub.yGa.sub.1-x-yN, where (0<x1, 0<y1, 0<x+y1).